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LUKAS WEBER – PHYSICS

lweber at flatironinstitute.org
0000-0003-4949-5529
Google Scholar
@lukas-weber


ABOUT

I am a postdoctoral researcher in theoretical condensed matter physics,
currently based in New York. My main research interests are strongly correlated
matter, in particular quantum magnets, and strong light-matter coupling in
cavity quantum electrodynamics.

My main method are large-scale quantum Monte Carlo simulations, where I have
experience in method development and the implementation of several
high-performance codes.


EMPLOYMENT

2022 – present
Postdoctoral Researcher Flatiron Institute New York, US
2022 – 2022
Postdoctoral Researcher Max Planck Institute for the Structure and Dynamics of
Matter Hamburg, DE
2018 – 2022
Doctoral researcher within the DFG research training group RTG1995 RWTH Aachen
University Aachen, DE


FUNDING

2022 – present
Cavity QED with two-dimensional quantum magnets Deutsche Forschungsgemeinschaft
Bonn, DE


EDUCATION

2018 – 2022
PhD in Physics RWTH Aachen University Aachen, DE
2016 – 2018
M. Sc. Physics RWTH Aachen University Aachen, DE
2013 – 2016
B. Sc. Physics RWTH Aachen University Aachen, DE


PUBLICATIONS

 1.  L. Weber, E. Viñas Boström, M. Claassen, A. Rubio, and D. M. Kennes,
     Cavity-renormalized quantum criticality in a honeycomb bilayer
     antiferromagnet,
     Commun Phys 6, 247 (2023)
 2.  L. Weber, A. Y. D. Fache, F. Mila, and S. Wessel,
     Thermal critical points from competing singlet formations in fully
     frustrated bilayer antiferromagnets,
     Phys. Rev. B 106, 235128 (2022)
 3.  L. Weber, N. Caci, and S. Wessel,
     Cluster quantum Monte Carlo study of two-dimensional weakly coupled
     frustrated trimer antiferromagnets,
     Phys. Rev. B 106, 035141 (2022)
 4.  A. Honecker, L. Weber, P. Corboz, F. Mila, and S. Wessel,
     Quantum Monte Carlo simulations of highly frustrated magnets in a cluster
     basis: The two-dimensional Shastry-Sutherland model,
     J. Phys.: Conf. Ser. 2207, 012032 (2022)
 5.  L. Weber, A. Honecker, B. Normand, P. Corboz, F. Mila, and S. Wessel,
     Quantum Monte Carlo simulations in the trimer basis: first-order
     transitions and thermal critical points in frustrated trilayer magnets,
     SciPost Phys. 12, 054 (2022)
 6.  N. Caci, L. Weber, and S. Wessel,
     Hierarchical single-ion anisotropies in spin-1 Heisenberg antiferromagnets
     on the honeycomb lattice,
     Phys. Rev. B 104, 155139 (2021)
 7.  E. S. Klyushina, J. Reuther, L. Weber, A. T. M. N. Islam, J. S. Lord, B.
     Klemke, M. Månsson, S. Wessel, and B. Lake,
     Signatures for Berezinskii-Kosterlitz-Thouless critical behavior in the
     planar antiferromagnet BaNi2V2O8,
     Phys. Rev. B 104, 064402 (2021)
 8.  J. L. Jiménez, S. P. G. Crone, E. Fogh, M. E. Zayed, R. Lortz, E.
     Pomjakushina, K. Conder, A. M. Läuchli, L. Weber, S. Wessel, A. Honecker,
     B. Normand, C. Rüegg, P. Corboz, H. M. Rønnow, and F. Mila,
     A quantum magnetic analogue to the critical point of water,
     Nature 592, 370-375 (2021)
 9.  L. Weber and S. Wessel,
     Spin versus bond correlations along dangling edges of quantum critical
     magnets,
     Phys. Rev. B 103, L020406 (2021)
 10. A. M. Golubev, J. Nuss, R. K. Kremer, E. E. Gordon, M. Whangbo, C. Ritter,
     L. Weber, and S. Wessel,
     Two-dimensional magnetism in α−CuV2O6,
     Phys. Rev. B 102, 014436 (2020)
 11. E. Torres, L. Weber, L. Janssen, S. Wessel, and M. M. Scherer,
     Emergent symmetries and coexisting orders in Dirac fermion systems,
     Phys. Rev. Research 2, 022005 (2020)
 12. L. Weber and S. Wessel,
     Nonordinary criticality at the edges of planar spin-1 Heisenberg
     antiferromagnets,
     Phys. Rev. B 100, 054437 (2019)
 13. L. Weber, F. Parisen Toldin, and S. Wessel,
     Nonordinary edge criticality of two-dimensional quantum critical magnets,
     Phys. Rev. B 98, 140403 (2018)

This page was generated automatically from my ORCID record.